System and Method for Calibrating an Automated Materials Handling System

ABSTRACT

A method of calibrating positions within a materials handling system, wherein the materials handling system includes multiple stations for carrying out tasks and a carrier that is movable between the multiple stations, includes the steps of: providing calibration points at a plurality of the multiple stations; moving the carrier to at least some of the calibration points; contacting the calibration points; recording the locations of the calibration points; and determining locations of key components of the stations based on the locations of the calibration points. In some embodiments, the method includes contacting the calibration points with a calibration tool, which may include: a cylindrical body; a groove in the cylindrical body sized and configured to receive jaws from the carrier; and a cylindrical upper flange positioned on an upper end of the cylindrical body. In this configuration, the tool can be gripped by the carrier and employed to perform a variety of calibration functions.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority from U.S. application Ser. No.12/349,626, filed Jan. 7, 2009, which claims priority from U.S.Provisional Patent Application No. 61/020,192, filed Jan. 10, 2008, thedisclosures of which are hereby incorporated herein by reference as ifset forth in their entirety.

FIELD OF THE INVENTION

The present invention is directed generally to automated materialshandling systems, and more specifically is directed to the calibrationof automated materials handling systems.

BACKGROUND OF THE INVENTION

Pharmacy generally began with the compounding of medicines, whichentailed the actual mixing and preparing of medications. Heretofore,pharmacy has been, to a great extent, a profession of dispensing, thatis, the pouring, counting, and labeling of a prescription, andsubsequently transferring the dispensed medication to the patient.Because of the repetitiveness of many of the pharmacist's tasks,automation of these tasks has been desirable.

Some attempts have been made to automate the pharmacy environment.Different exemplary approaches are shown in U.S. Pat. No. 5,337,919 toSpaulding et al. and U.S. Pat. Nos. 6,006,946; 6,036,812 and 6,176,392to Williams et al. The Williams system conveys a bin with tablets to acounter and a vial to the counter. The counter dispenses tablets to thevial. Once the tablets have been dispensed, the system returns the binto its original location and conveys the vial to an output device.Tablets may be counted and dispensed with any number of countingdevices. Drawbacks to these systems typically include the relatively lowspeed at which prescriptions are filled and the absence in these systemsof securing a closure (i.e., a lid) on the container after it is filled.

One additional automated system for dispensing pharmaceuticals isdescribed in some detail in U.S. Pat. No. 6,971,541 to Williams et al.This system has the capacity to select an appropriate vial, label thevial, fill the vial with a desired quantity of a selected pharmaceuticaltablet, apply a cap to the filled vial, and convey the labeled, filled,capped vial to an offloading station for retrieval.

Although this particular system can provide automated pharmaceuticaldispensing, certain of the operations may be improved. In particular, itmay be convenient for an owner of an automated pharmaceutical dispensingmachine to be able to calibrate the machine after installation, afterthe machine has been moved within a pharmacy, or if one or moreposition-sensitive components or stations has been replaced. Calibrationcan be important for successful operation of the machine, as the roboticarm must be able to position itself reliably and consistently relativeto the different components/stations of the machine (particularly thedifferent dispensers for vials and tablets and multiple offloadingcompartments) in order for the machine to operate reliably.

SUMMARY OF THE INVENTION

As a first aspect, embodiments of the present invention are directed toa calibration tool for an automated materials handling system, whereinthe materials handling system has a carrier that is configured to movebetween multiple stations within the system. The tool comprises: acylindrical body; a groove in the cylindrical body sized and configuredto receive jaws from the carrier; and a cylindrical flange positioned onan end of the cylindrical body. In this configuration, the tool can begripped by the carrier and employed to perform a variety of calibrationfunctions.

As a second aspect, embodiments of the present invention are directed toa calibration system for an automated materials handling system, thematerials handling system having a carrier that is configured to movebetween multiple stations within the materials handling system. Thecalibration system comprising: a pair of gripping jaws attached to thecarrier; and a tool having a groove and a cylindrical flange.

As a third aspect, embodiments of the present invention are directed toa method of calibrating positions within a materials handling system,wherein the materials handling system includes multiple stations forcarrying out tasks and a carrier that is movable between the multiplestations. The method comprising the steps of: providing calibrationpoints at a plurality of the multiple stations; moving the carrier to atleast some of the calibration points; contacting the calibration points;recording the locations of the calibration points; and determininglocations of key components of the stations based on the locations ofthe calibration points. In some embodiments, the method includescontacting the calibration points with a calibration tool, which may beconfigured as described above.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a flow chart depicting operations that can be carried out byan automated pharmacy machine according to embodiments of the presentinvention.

FIG. 2 is a front perspective view of an automated pharmacy machineaccording to embodiments of the present invention.

FIG. 3 is a rear perspective view of the automated pharmacy machine ofFIG. 2 with the outer skin removed to permit visual access to componentshoused therein.

FIG. 4 is an enlarged perspective view of the gripping unit of theautomated pharmacy machine of FIGS. 2 and 3.

FIGS. 5A-5C are top, front and perspective views of a calibration tooluseful in calibrating the automated pharmacy machine of FIGS. 2 and 3.

FIGS. 6A-6C are schematic diagrams illustrating the geometry used inCurved Surface Contact calibration.

FIGS. 7A and 7B are schematic diagrams illustrating an exemplary groovefor use in Tool and Groove Contact calibration.

FIG. 8 is a front section view of the automated pharmacy machine ofFIGS. 2 and 3 taken along lines 8-8 of FIG. 2.

FIG. 9 is a rear section view of the automated pharmacy machine of FIGS.2 and 3 taken along lines 9-9 of FIG. 2.

FIG. 10 is an enlarged view taken from FIG. 9 of the base plate and postof the labeler station of the automated pharmacy machine of FIGS. 2 and3.

FIG. 11 is an enlarged view taken from FIG. 8 of the manifold thatprovides air to the bins of the dispensing station of the automatedpharmacy machine of FIGS. 2 and 3 showing grooves used to calibrate thepositions of the bins.

FIG. 12 is an enlarged view taken from FIG. 9 of the stage of thecapping station of the automated pharmacy machine of FIGS. 2 and 3.

FIG. 13 is an enlarged view taken from FIG. 9 of the offload station ofthe automated pharmacy machine of FIGS. 2 and 3 showing a gap in theframe used to calibrate the positions of the offload chutes.

DETAILED DESCRIPTION OF EMBODIMENTS OF THE INVENTION

The present invention will now be described more fully hereinafter, inwhich preferred embodiments of the invention are shown. This inventionmay, however, be embodied in different forms and should not be construedas limited to the embodiments set forth herein. Rather, theseembodiments are provided so that this disclosure will be thorough andcomplete, and will fully convey the scope of the invention to thoseskilled in the art. In the drawings, like numbers refer to like elementsthroughout. Thicknesses and dimensions of some components may beexaggerated for clarity.

Unless otherwise defined, all terms (including technical and scientificterms) used herein have the same meaning as commonly understood by oneof ordinary skill in the art to which this invention belongs. It will befurther understood that terms, such as those defined in commonly useddictionaries, should be interpreted as having a meaning that isconsistent with their meaning in the context of the relevant art andwill not be interpreted in an idealized or overly formal sense unlessexpressly so defined herein.

The terminology used herein is for the purpose of describing particularembodiments only and is not intended to be limiting of the invention. Asused herein, the singular forms “a”, “an” and “the” are intended toinclude the plural forms as well, unless the context clearly indicatesotherwise. It will be further understood that the terms “comprises”and/or “comprising,” when used in this specification, specify thepresence of stated features, integers, steps, operations, elements,and/or components, but do not preclude the presence or addition of oneor more other features, integers, steps, operations, elements,components, and/or groups thereof. As used herein the expression“and/or” includes any and all combinations of one or more of theassociated listed items.

In addition, spatially relative terms, such as “under”, “below”,“lower”, “over”, “upper” and the like, may be used herein for ease ofdescription to describe one element or feature's relationship to anotherelement(s) or feature(s) as illustrated in the figures. It will beunderstood that the spatially relative terms are intended to encompassdifferent orientations of the device in use or operation in addition tothe orientation depicted in the figures. For example, if the device inthe figures is turned over, elements described as “under” or “beneath”other elements or features would then be oriented “over” the otherelements or features. Thus, the exemplary term “under” can encompassboth an orientation of over and under. The device may be otherwiseoriented (rotated 90 degrees or at other orientations) and the spatiallyrelative descriptors used herein interpreted accordingly.

Also, as used herein, the terms “downstream” and “upstream,” which areoften used in manufacturing environments to indicate that certainmaterial being acted upon is farther along in the manufacturing processthan other material, are intended to indicate relative positions ofcomponents along a path followed by a substantially continuous papersheet that travels along and through the components. A component that is“downstream” from another component means that the first component ispositioned farther along the paper path, and a component that is“upstream” from another component means that the first component isnearer the origin of the paper path. It should be noted that, relativeto an absolute x-y-z coordinate axis system, these directions shift asthe paper is conveyed between different operations. When they occur,these shifts in absolute direction are noted hereinbelow, and thedownstream direction is redefined with reference to structuresillustrated in the drawings.

Well-known functions or constructions may not be described in detail forbrevity and/or clarity.

As described above, the illustrated embodiment of the invention relatesgenerally to a system and process for dispensing pharmaceuticals. Anexemplary process is described generally with reference to FIG. 1. Theprocess begins with the identification of the proper container, tabletsor capsules and closure to be dispensed based on a patient'sprescription information (Box 20). A container of the proper size isdispensed at a container dispensing station (Box 22), then moved to alabeling station (Box 24). A printing station prints a label (Box 25)that is applied at the labeling station (Box 26), after which thecontainer is transferred to a tablet dispensing station (Box 28), fromwhich the designated tablets are dispensed in the designated amount intothe container (Box 30). The filled container is then moved to a closuredispensing station (Box 32), where a closure of the proper size has beendispensed (Box 34). The filled container is secured with a closure (Box36), then transported to an offload station and offloaded (Box 38).

Techniques are illustrated and described with respect to an automatedpharmaceutical dispensing machine, but may be employed with anyautomated system that includes a robotic arm, including manufacturing,distribution, sorting, dispensing, and other systems.

Overall System and Carrier Unit

A system that can carry out this process is illustrated in FIGS. 2 and 3and designated broadly therein at 40. The system 40 includes a supportframe 44 for the mounting of its various components. The system 40generally includes as operative stations a controller (representedherein by a graphics user interface monitor 42), a container dispensingstation 58, a labeling station 60, a printing station 61, a tabletdispensing station 62, a closure station 64, an offloading station 66,and an offloading carousel 67. In the illustrated embodiment,containers, tablets and closures are moved between these stations with asingle carrier unit 68; however, in some embodiments only a singlecarrier may be employed, or one or more additional carriers may beemployed. The operation of the container dispensing station 58, thelabeling station 60, the tablet dispensing station 62, the closurestation 64, and the offloading station 66 are described in, for example,U.S. patent application Ser. Nos. 11/599,526; 11/599,576; 11/679,850;and 11/111,270, and U.S. patent application Ser. No. 11/927,865, thedisclosure of each of which is hereby incorporated herein in itsentirety.

The carrier unit 68 comprises a top rail 72 and a bottom rail (notshown), each of which is mounted to the frame 44. A vertical rail 76 isslidably mounted between the top rail 72 and bottom rail respectiveslide brackets (slide bracket 75, which is mounted on the top rail 72,is shown in FIG. 3). A toothed belt is attached to the slide bracket 75and to a motor 77 a that is mounted to the frame 44 for driving thevertical rail 76 to different positions along the horizontal rails. Atraveler unit 78 (FIG. 4) is slidably mounted on the vertical rail 76. Atoothed belt (not shown) is connected to the traveler unit 78 and amotor 79 a mounted on the slide bracket 75 for driving the traveler unit78 vertically along the vertical rail 76.

Referring again to FIG. 4, the traveler unit 78 includes a body 83around which a gripper unit 80 revolves. The gripper unit 80 is mountedin a set of upper and lower tracks 88, 89 that extend circumferentiallyaround the body 83. The gripper unit 80 includes an arm 82 and a pair ofjaws 84. The jaws 84 include a pair of fingers 84 a and a yoke 84 b onwhich the fingers 84 a are mounted. A motor 81 a is mounted on the body83 and drives the gripper unit 80 around a vertical axis A1 (definedgenerally by the vertical rail 76) via a gear 81 that engages teeth in atrack 85 on the upper track 89.

By virtue of this configuration, the gripper unit 80 can be driven toany position along an “X-Z” plane defined by the horizontal rails 72, 74(the X-axis) and the vertical rail 76 (the Z-axis). The gripper unit 80can also be revolved to any angular (θ) position relative to the Z-axis.As such, the gripper unit 80 can be directed to the various stations ofthe system 40 to carry out operations at each. Movement of the gripperunit 80 and the jaws 84 is controlled by the controller 42, whichactivates the motors 77 a, 79 a, 81 a.

Position Detection

A. Use of Servo-Controlled Motors to Detect Position

Each of the motors 77 a, 79 a, 81 a is a servo-controlled motor. Thecontroller 42 monitors the current drawn through the motor; because thecurrent flowing through the windings of the motor is proportional to thetorque of the motor shaft, a limit on the available current can limitthe force applied by the motor or any structure coupled thereto. Thesefeatures of the motor can be employed to assess the position of astationary structure. For example, the jaws 84 of the gripper unit 80can be instructed to move to a particular location, or can be instructedto move at a target velocity for a specified time period. If astationary structure impedes the movement, the positioning error of themotor increases until a threshold is reached; the position of the jaws84 can then be noted by the controller 42 as indicating the presence andposition of the stationary structure.

B. Contact Points of Carrier Unit

Although the jaws 84 themselves may be employed to contact structureswithin the system 40 for the purpose of determining their positions, insome embodiments worm gears used to drive the fingers 84 a can wear overtime and, as a result, introduce inaccuracy. The yoke 84 b is less proneto introduce inaccuracy; however, for some structures it is difficult orimpossible to contact the structure with the yoke 84 b. Accordingly, astanchion or pin may be positioned on or near the structure that theyoke 84 b can reach. As an alternative, a tool gripped by the jaws 84and extending beyond the length of the fingers 84 a may be employed.

An exemplary tool for such use is illustrated in FIGS. 5A-5C anddesignated at 100. The tool 100 has a generally cylindrical body 102with a circumferential groove 104, a flat bottom surface, and a lowerflange 106. The fingers 84 a of the jaws 84 can grip the tool 100 in thegroove 104; in some embodiments, the groove 104 is sufficiently deep(between about 0.3 and 0.6 inches) that the fingers 84 a can fitcompletely within the groove 104. The body 102 should have a radiuslarge enough (typically between about 0.5 and 1 inch) that the bottomsurface of the body 102 can be used to descend upon and (a) contact ahorizontal surface or (b) lowered onto a post. The flange 106 iscylindrical and should be thick enough to support the weight of the tool100, and its diameter should be selected so that it can fit within amachined groove or other reference point. Typically, the diameter of theflange 106 is between about 1.5 and 2.5 inches, and the thickness of theflange 106 is between about 0.1 and 1.0 inch. Also, typically thediameter of the flange 106 is at least about 0.5 inches greater than thediameter of the body 102. In some embodiments, the tool 100 may haveboth upper and lower flanges, which may be of the same or differentdiameters, or may lack a flange entirely.

In the illustrated embodiment, the tool 100 is stored on the frame 44;more specifically, the tool 100 is stored on a post 190 located on ashelf 192 below the offload station 66 (see FIG. 9); however, in otherembodiments the tool 100 may be stored in any location from which it canbe retrieved reliably.

C. Calibration Maneuvers

In order to locate the positions of different structures within thesystem 40, the gripper 80, with or without the tool 100, can be used tocontact the structure of interest. In some embodiments, the position ofthe structure of interest is determined relative to a structure of knownposition. For example, in the illustrated embodiment, a homing sensor110 is located at one end of the top rail 72, another homing sensor (notshown) is located at the opposite end of the bottom rail (also notshown), homing sensors 114, 116 are located at either end of thevertical rail 76, and a homing sensor 118 is located on the body 83 ofthe gripper unit 80. As an initial maneuver, the gripper unit 80 maylocate one or more of the homing sensors to establish a baselineposition.

1. Horizontal Surface Contact

With this technique, the bottom of the yoke 84 b or the bottom surfaceof the tool 100 is driven into contact with a flat horizontal surface.Examples of reference point surfaces are shelves of the offloadingstation 66, a small vertical post, or any kind of inset or offset ledge.In order for this maneuver to be successful, the tool 100 should be ableto contact the surface without bumping into any other features nearby,the feature providing the surface should not interfere with normaloperation of the carrier unit 68, and the tolerance stack-up between thesurface and the actual pick-up/drop-off point should be minimized.

The procedure for finding a horizontal surface is described as follows.Initially, the carrier 68 is positioned so that the yoke 84 b or thetool 100 is positioned directly above or below the reference point. Aforce-limited move is then performed onto the reference point. TheZ-axis position (i.e., the height of the surface) can then be recordedby the controller 42.

Another procedure for Horizontal Surface Contact (which employsincrementing the Z-position of the carrier 68 or tool 100) is describedbelow in connection with Horizontal Surface Clearing.

2. Horizontal Surface Clearing

This technique can also be used to locate a surface in the Z-direction.With this technique, either the yoke 84 b or the tool 100 is moved intoa lip or other protrusion with an upper or lower flat horizontalsection. The height of the yoke 84 b or tool 100 is incrementallyadjusted until the tool 100 or yoke 84 b clears the contact point. Thistechnique is typically more time-consuming than the horizontal surfacecontact method discussed above, but places much less stress on thefeature being located. Therefore, it may be more suitable for locatingplastic features that may be present on the dispensing cells in thetablet dispensing station 62 or drop-off bins in the offloading station66.

The procedure for locating such a feature is as follows. First, the tool100 or yoke 84 b is positioned directly adjacent and level with thesurface of the reference point. A θ-axis force-limited move into thereference point, and the θ and Z positions are recorded. The tool 100 oryoke 84 b is withdrawn, its Z-position is modified (typically byone-half of the desired calibration precision), and the maneuver isrepeated. If the last θ position exceeds the prior θ position by a valuelarge enough to indicate clearance of the feature, the last Z positionis recorded with the controller 42 as its vertical location; otherwise,modification of the Z-position is repeated until this clearancecondition is reached.

Those skilled in this art will appreciate that a similar,Z-position-incrementing technique can be used for Horizontal SurfaceContact, with the controller 42 detecting contact rather than clearing.

3. Curved Surface Contact

This technique can be used to locate a feature in X and θ coordinates,before converting the coordinates to X and Y. A circularly curvedsurface of known radius is located against the edge of the tool 100 (seeFIG. 6A). The lower circle in FIG. 6A represents the cross-section ofthe target, and the upper circle represents the cross-section of thetool 100. This alignment geometry can be achieved by contacting the tool100 into the reference point using a force limited move. The exactcontact point of the tool 100 and the target is unimportant for thiscalculation, allowing approximate locations of the target to be used forthe initial contact. However the tool 100 should contact only the radiusof the target, not flat surfaces (it should be noted that a sharp edgecan be modeled as a circle of small radius). The X and Y locations ofthe center of the tool 100 can be calculated with known X and θlocations using simple geometry and recorded.

Next, the tool location is incremented in the X direction, and anotherforce limited move is performed so that the tool 100 contacts the targetat another point on the same curved surface (see FIG. 6B). The X and Ylocations of the center of the tool are recorded again.

These steps yield the known geometry picture shown in FIG. 6C. The twocontact points enable the definition of two circles of known radiustangent to a third circle of known radius. Geometrically, there are onlytwo possible locations for the center of the target circle. Thelocations of each of these centers can be computed; based on thephysical realities of the system 40, the solution that is on the “wrong”side of the tool 100 can be discarded.

4. Tool and Groove Contact

Referring now to FIGS. 7A and 7B, with this technique the tool 100 isinserted into a narrow groove having a length selected to be largeenough so that the tool 100 has a distinctive clearance on both sides ofit when inserted (typically, the groove length is between about 2 and 4inches). The extreme ends of the groove can be detected when the tool100 reaches a local absolute maximum distance away from center as itmoves across the groove. The height of the groove should be chosen sothat force-controlled moves can be performed into the top and/or bottomedges of the groove using the same procedure described above forHorizontal Surface Contact.

Either or both of the lateral edges of the groove may be located by thefollowing procedure. An initial position is selected such that the tool100 can be moved in the θ-direction toward the edge of the groove. Aforce-controlled move in the θ-direction is then performed, and theposition is recorded as the “outside” position. The position of the tool100 is then incremented in the X-direction by ½ of the requiredreference point precision, and another force-controlled move in theθ-direction is performed. If θ is equal to the last position (withinsome tolerance) and greater than the outside position (by some minimumamount related to the groove depth), then the edge has been found, andthe X- and θ-coordinates can be recorded.

D. Illustrative Calibration Maneuvers for Pharmaceutical System

The system 40 may include a number of reference points for calibration:as examples, the labeler station 60, the closure station 64, differentsections of the offloading station 66 (e.g., sorted drop-off, bulkdrop-off, exception drop-off, etc.), individual bins of the tabletdispensing station 62, and the homing sensors 112, 114, 116, 118. Foreach subassembly, calibration points should be chosen that minimize thecumulative manufacturing tolerance between the calibration points andthe actual locations where a vial is picked up, conveyed or dropped off.

At each stage, the cumulative manufacturing tolerance between the mainrobot homing sensors and each interface point may be assumed to be aparticular value, e.g., ±0.25 inches. Additionally, the choice of anygiven reference point may become a high-precision interface formanufacturing.

Exemplary reference points are discussed below.

1. Homing Sensors

Referring now to FIG. 4, manufacturing tolerances in the homing sensors112, 114, 116 (i.e., the X- and Z-axis sensors) change the relationshipbetween those sensors and the target reference points in an exactlylinear way. As such, their required placement precision is relativelylow, as any manufacturing variability for these parts simply adds to themaximum total distance between the sensor and the reference point, whichis accounted for in each calibration procedure by the choice of initialposition.

In contrast, the θ-axis is non-linearly related to the Y position of anyreference point. Both the curved surface contact and the tool-in-grooveinterfaces result in a reference geometry that is defined relative to acentered θ-axis. Thus, either the homing sensor 118 can be well-alignedwith true centerline (i.e., with the X-axis), via precision machining orthe like, or a target can be provided that is near true centerline. Inthis latter technique, a pair of moves can be performed into a singlelocation (in this instance, that location is located at the tool shelf192). The θ-position after both moves can be recorded, and the averagebetween the two used as a reference for 90 degrees.

2. Z-Axis Twist

In addition to a single point being calibration for “true center” fortheta, the system can calibrate the amount of Z-axis twist present inthe system. Without this calibration, if the gripper unit 80 rotates tothe same angular position at the top and bottom of the vertical rail 76,it may not be extending at the same angle because the vertical rail 76has some twist. Thus, in addition to calibrating the single θ pointdescribed above, the positions of each cell manifold from top to bottomcan be calibrated to determine how much twist is present. After thiscalibration, a θ measurement will orient itself correctly depending onthe height of the carriage.

To calibrate for Z-axis twist, a force limited move is performed pushingthe tool 100 against a cell manifold 152 at some location on themanifold. Then the gripper unit 80 is turned around to be reverse-facingand moved to the same location again. (Note: this is very similar to thehoming sensor calibration described above.) The θ location after each ofthe moves is recorded. Using these two values a θ offset at this heightwithin the system is determined. This is repeated for each of themanifolds 152. These data provide an array of θ offsets for the totallength of travel for the length of the vertical rail 76. This procedurecan effectively model the twist of the z-axis within the system.

Later, when a move is performed to any location in the system, the arrayof θ offsets is used to determine how much θ offset to apply to thecalculation. Thus, every time a move is performed during normaloperation, the height at which the move is performed can be used toindex into the array and extrapolate the θ offset at that particularheight.

3. Labeling Station

To determine the position of the labeling station 60 (where the carrierunit 68 picks up an empty, uncapped, labeled vial), a small-diameterpost 200 of approximately ¼ inch OD can be included on the labeler baseplate 61 (see FIGS. 9 and 10), positioned such that (a) it does notinterfere with normal labeling and pick-up operation and (b) it can befelt with the yoke 84 b in Z-, X-, and θ-positions. The carrier unit 68conveys the yoke 84 b to the post 200, where horizontal surface clearingand curved surface contact maneuvers are performed.

The pick-up positioning accuracy in the Z-direction for the labelingstation 60 is additive with the required vertical positioning accuracyat the bins of the tablet dispensing station 62. The pick-up positioningaccuracy in the X- and Y-directions for the labeling station 60 is basedon the ability of the gripper unit 80 to pick up a vial at thislocation; it is not additive to targeting accuracy at the closurestation 64 since the gripper unit 80 automatically centers a vialbetween the jaws 84 when it picks up the vial.

4. Dispensing Bin Arrays

Individual bins of the tablet dispensing station 62 are mated verticallywith a vial for dispensing by making positive contact under aforce-limited upward move. This positive contact is intended to ensurethat no pills will ever be lost through the gap between the bin nozzleand the vial. Horizontally, a typical bin nozzle output diameter is1.000 inches across, and the narrowest common vial diameter is 1.125inches. That yields a horizontal mating tolerance of about +/− 0.062inches. Vertically, the vial should be no more than 1 mm (0.032) awayfrom the nozzle.

To calibrate for a proper horizontal (i.e., X- and θ-direction)interface with individual bins, in some embodiments, a series of grooves300 may be cut into the bin manifold that are spaced at a known distancefrom the individual bins (see FIGS. 8 and 11). The grooves can belocated with a tool-in-groove maneuver as described above.Alternatively, a structure such as a bin nozzle mating flange can belocated with a curved surface contact maneuver; if this maneuver isemployed, it may performed on all bins, or only on a limited number ofbins necessary to develop reliable position data.

5. Closure Station

The location of the closure station 64 needs to be known because afilled, labeled vial is placed therein for the application of a cap orother closure. Turning to FIGS. 9 and 12, the carrier unit 68 can locatethe upper surface of the stage 400 of the closure station 64 with aHorizontal Surface Contact maneuver using the tool 100 (in someembodiments, Horizontal Surface Clearing may be employed). In someembodiments, the closure station 64 need not be located in the X- andθ-directions because the drop-off and pick-up tolerances for the closurestation 64 may be very large for successful docking. If this is not thecase, the tool 100 can be used to find a peripheral edge of the stage400. Curved Tool Contact can then be employed to find the center of thestage 400.

6. Off-Load Station

A typical off-load station, such as the station 66, may have multiplestructures for potential calibration. In the illustrated embodiment, theoverflow area is rather large (a drawer approximately 6 inches by 12inches) and as such may not require calibration. The exception drop-offarea consists of three shelves about 6 inches in width and may requireonly Z-direction calibration (e.g., finding the top surface of eachshelf with a horizontal surface contact maneuver). The sorted drop-offarea has multiple rows of sloped bins, the inlets to which can belocated with a tool-in-groove maneuver in cutaway areas 230 in the frame(see FIGS. 9 and 13) or by Horizontal Surface Contact and Curved ToolContact maneuvers with the lips of individual drop-off bins. HorizontalSurface Contact and Curved Surface Contact can be employed to locate theexception carousel 67 of the offload station 66.

The foregoing is illustrative of the present invention and is not to beconstrued as limiting thereof. Although exemplary embodiments of thisinvention have been described, those skilled in the art will readilyappreciate that many modifications are possible in the exemplaryembodiments without materially departing from the novel teachings andadvantages of this invention. Accordingly, all such modifications areintended to be included within the scope of this invention. Theinvention is defined by the following claims, with equivalents of theclaims to be included therein.

1. A calibration tool for an automated materials handling system, thematerials handling system having a carrier that is configured to movebetween multiple stations within the system, the tool comprising: acylindrical body; a groove in the cylindrical body sized and configuredto receive jaws from the carrier; and; a cylindrical flange positionedon an end of the cylindrical body.
 2. The tool defined in claim 1,wherein the flange has a diameter that is at least 0.5 inches greaterthan a diameter of the body.
 3. The tool defined in claim 1, wherein theflange has a diameter of between about 1.5 and 2.5 inches.
 4. The tooldefined in claim 1, wherein the flange has a thickness of between about0.1 and 1.0 inches.
 5. The tool defined in claim 1, wherein the body hasa flat lower surface.
 6. The tool defined in claim 1, wherein the flangehas a flat upper surface.
 7. A calibration tool for an automatedmaterials handling system, the materials handling system having acarrier that is configured to move between multiple stations within thesystem, the tool comprising: a cylindrical body with a flat lowersurface; a groove in the cylindrical body sized and configured toreceive jaws from the carrier; and; a cylindrical flange positioned onan upper end of the cylindrical body, the flange having a flat uppersurface.
 8. The tool defined in claim 7, wherein the flange has adiameter that is at least 0.5 inches greater than a diameter of thebody.
 9. The tool defined in claim 7, wherein the flange has a diameterof between about 1.5 and 2.5 inches.
 10. The tool defined in claim 7,wherein the flange has a thickness of between about 0.1 and 1.0 inches.11. A calibration tool for an automated materials handling system, thematerials handling system having a carrier that is configured to movebetween multiple stations within the system, the tool comprising: acylindrical body; a groove in the cylindrical body sized and configuredto receive jaws from the carrier; and; a cylindrical flange positionedon an end of the cylindrical body; wherein the flange has a diameter ofbetween about 1.5 and 2.5 inches that is at least 0.5 inches greaterthan a diameter of the body.
 12. The tool defined in claim 11, whereinthe body has a flat lower surface.
 13. The tool defined in claim 11,wherein the flange has a flat upper surface.